RU2125334C1 - Method for reverse pulsed conversion of dc voltage - Google Patents

Abstract

FIELD: electrical engineering; DC-to-DC voltage conversion. SUBSTANCE: during first phase of periodic process cycle, transformer magnetic energy and first capacitor energy increase as transformer is connected to power supply through closed control switch and first capacitor while energy of second capacitor connected to transformer by means of closed control switch decreases; during second phase of cycle, dose of magnetic energy of transformer obtained during first phase, second dose of energy of power supply and some portion of first capacitor energy are conveyed to load and increase energy of second capacitor with control switch held open and transformer connected by means of closed transmitting switch to power supply through second capacitor and to first capacitor. Newly introduced are definite switching delay circuits for controlling alternate change-over of semiconductor devices of switches; switching paths of these semiconductor devices are formed by connecting capacitors to them; in addition, half-cycle of capacitance loop fluctuations of first and second capacitors as well as of transformer inductances is set to be lower than that of second phase of cycle. Output energy of power supply is consumed during both phases of period; energies of transformer, first and second capacitors vary from their mean values and voltages across open control and transmitting switches do not exceed supply voltage and have spike-free flat-top trapezoidal waveform. EFFECT: improved safety of semiconductor device path and provision for obtaining several finely matched output channels. 2 cl, 2 dwg

Description

 The method of pulsed flyback DC voltage conversion relates to electrical engineering, in particular to DC to DC converters and voltage regulators, and can be used in power supply systems and electric drives.

 A known method of pulsed flyback DC voltage conversion, in which the energy of the inductor-transformer is increased at the stage of the closed state of the regulating key from the power source, and at the stage of the open state of the regulating key, the energy of the inductor-transformer is partially or completely transferred to the load through the reverse-connected rectifier diode [Polikarpov A.G., Sergienko E.F., Single-cycle voltage transformations in REA power supply devices, M., Radio and communication, 1989, p. 61, 67 ... 68]. The disadvantages of this method are the reduced conversion efficiency due to significant losses in the inductor-transformer, since the conversion power is provided only by the pulsation of the electromagnetic energy of this main component and the conversion frequency, and a large voltage value on the open control key, exceeding the supply voltage, with an additional switching surge voltage due to imperfect electromagnetic coupling of the primary and secondary power windings and a sharp surge in current in the rectifier The scintillating diode, as well as the difficulty of providing a safe path for the transistor of the key. This leads to the need to overestimate the installation power of the power switch and the inductor-transformer to obtain the necessary reliability, which leads to a deterioration in the energy, weight, size and economic performance of the converter.

 The closest technical solution is the method of pulsed DC voltage conversion, in which at the closed stage of the regulating transistor switch the magnetic energy of the transformer is increased, as well as the energy of the power source is transmitted through the directly connected rectifier diode to the load, and at the open stage of the control key the magnetic energy of the transformer is transferred to an additional capacitor and through a reverse-connected rectifier diode to the load, where so the part of the energy of the additional capacitor obtained at the beginning of this stage returns through the auxiliary transistor switch. [Polikarpov A. G., Sergienko EF, Single-cycle voltage converters in power supply devices CEA, M., Radio and communications, 1989, p. 68 ... 70]. The disadvantage of this method is the energy consumption from the power source only at the first stage when the control switch is closed, the increased voltage on the open control and auxiliary switches exceeds the supply voltage, and the need for filtering inductance, included after the rectifier diodes, which complicates the implementation of a multi-channel converter.

 The main technical objective of the proposed method is to achieve uniformity of current consumption from the power source, reducing losses in the transformer, reducing the voltage on the power switch in the open state, forming the path of its switching and reducing the installation power, improving the quality of the output voltage and multi-channel output.

 The problem is solved in that in the proposed method for pulsed flyback conversion of DC voltage at the first stage of the period of the periodic process, the magnetic energy of the transformer and the energy of the first capacitor are increased when the transformer is connected to the power source through a closed control key and the first capacitor and the energy of the second capacitor connected to transformer with a closed control key, and in the second stage of the period, the dose of magn tnoj power transformer, a second dose and energy of the source of the first capacitor energy transferred to the load and increase the energy of the second capacitor at the open position and the controlled switch connected transformer closed transmitting the key to the power source via the second capacitor and the first capacitor. In addition, certain switching delays are introduced for controlling the switching of semiconductor switch devices one by one, and the switching paths of these semiconductor devices are formed by connecting capacitors to them, and a half-cycle of oscillations of the capacitance circuit of the first and second capacitors and transformer dissipation inductors is set to be shorter than the duration of the second stage of the period.

 The energy from the power source is consumed at both stages of the period, the energy of the transformer, the first and second capacitors fluctuate relative to their average values, and the voltages on the open control and transmitting keys do not exceed the supply voltage, and they have a trapezoidal shape with a flat top without emissions, which ensures key reliability and the ability to obtain multiple output channels with good agreement.

 An analysis of the known technical solutions showed that the proposed method of pulsed flyback DC voltage conversion, which consists in the above phased metered increase and transfer of energy of the transformer, the first and second capacitors with its consumption from the power source at both stages of the period with the direct transfer of part of the energy from the power source to the load at the second stage, it exhibits new properties consisting in increasing the conversion efficiency, reliability and quality of electric opitaniya and reduced weight and size converter.

 The invention is illustrated by drawings.

 In FIG. 1 shows a structural diagram of a device that represents one of the implementations of the proposed method of flyback conversion and DC voltage regulation.

 In FIG. 2 shows diagrams of voltages and currents in various nodes of the device with indices corresponding to their designation in FIG. 1.

 The proposed method is implemented in the device shown in FIG. 1. The device contains terminals 1 for connecting a power source, a control unit 2 with two outputs - the first 3 and second 4, connected to the inputs of two power switches - regulating 5 and transmitting 6, respectively. In this case, the power switches 5 and 6 are connected in series with their outputs, forming a rack, and consist of the semiconductor device 7 (8), the capacitor 9 (10) and the parallel-parallel diode 11 (12) connected to the outputs of the keys, respectively, with the power switch input 5 (6) is connected to the input of the semiconductor device 7 (8); and parallel to the key rack connected to the input terminals 1, a rack of two series-connected capacitors is connected - the first 13 and second 14, while the primary winding of the transformer 15 is connected between the midpoints of the key racks and capacitors, while the secondary winding of the transformer 15 is through a rectifier the diode 16 is connected to a capacitor 17, to which the load connection terminals 18 are connected.

The voltage conversion is as follows. The control unit 2 generates opposite-phase alternating rectangular pulses of voltage U ₃ , U ₄ alternating with a small switching delay between the slice of one and the front of the other, with a conversion frequency and duration, which are determined by the selected control algorithm and the feedback law. These pulses U ₃ , U ₄ are supplied to the inputs of power switches 5, 6 and further to the inputs of semiconductor devices 7, 8 (for example, MOS transistors), respectively, ensuring their alternate switching.

 The closed key 5 increases the energy of the transformer 15 and the first capacitor 13 in the circuit "terminals of the power supply (constant voltage) 1 - the first capacitor 13 is a circuit with a key 5, the primary winding of the transformer 15 and the second capacitor 14". In this case, at the same time, part of the energy of the second capacitor 14 is released along the circuit "second capacitor 14 - key 5 - primary winding of the transformer 15". At this stage, the rectifier diode 16 is locked with a reverse bias voltage, and energy is supplied to the terminals of the load 18 from the capacitor 17.

 The closed key 6 transmits the energy of the power source 1, the first capacitor 13 and the transformer 15 to the load and increases the energy of the second capacitor 14 in the circuit "power supply terminals 1 - the second capacitor 14 - circuit with the key 6, the primary winding of the transformer 15 and the first capacitor 13" . To the conclusions of the load 18, the energy comes from the secondary winding of the transformer 15 and the capacitor 17.

The transfer characteristic for the proposed method of flyback conversion and DC voltage regulation in a simplified form is linear in terms of the period fill factor K ₃ = T ₁ / (T ₁ + T ₂ )
U _o / U _pit = K _Tr K _e
Where
U _o , U _pit - output voltage and power source;
K _Tr - the transformation ratio of the transformer;
T ₁ and T ₂ - the duration of the stages of the conversion period.

The current of the rectifier diode 16 is a combination of the transmitted fractions of the current of the power source, the second capacitor of the rack, and the magnetization current of the transformer and gradually increases from the zero level (I ₁₆ ), and with a half-cycle of oscillations of the circuit with capacitances of the first 13 and second 14 capacitors and a dissipation inductance of transformer 15 less the second stage of the period, drops to zero at its end, which contributes to the soft switching diodes keys.

The formation of the switching path of the semiconductor switch devices and the quality of the voltage conversion are provided by a certain delay of the voltage front of one control pulse U ₃ (U ₄ ) relative to the voltage cut of another control pulse U ₄ (U ₃ ). At the beginning of each stage of the period after the transistor 7 (8) is turned off, the current of the circuit stage “capacitor 13 (14) - primary winding of the transformer 15 - key 5 (6)" is divided in the middle of the key rack, recharging the key capacitor to the charge of the capacitor 9 (10) and discharging the capacitor 10 (9). In this case, the voltage at the switches varies according to the quasilinear law. When the capacitor 10 (9) is completely discharged to zero, and the capacitor 9 (10) is charged to the supply voltage, the current continues its path through the diode 12 (11), limiting the voltage on the keys. During this phase of the stage, the front of the control pulse U ₄ (U ₃ ) is supplied and the transistor 8 (7) is turned on when the voltage is zero (U ₈ , U ₇ ).

 Thus, the proposed device allows you to implement the proposed method, which provides the conversion of constant voltage with improved efficiency, reliability and quality of power supply.

Claims (2)

 1. A method of flyback pulsed conversion of constant voltage, according to which at the first stage of the period of the periodic process, energy is accumulated in the transformer by connecting its primary winding to the constant voltage source through a closed control key, at the second stage of the period, the energy accumulated at the first stage of the period, transfer to the load when the control key is open from the secondary winding of the transformer through a rectifying diode, characterized in that on in the first stage of the period, energy storage is carried out through the first capacitor included in the energy transfer circuit between the constant voltage source and the primary winding of the transformer, while energy storage is carried out on it, in addition, in the first stage of the period, an additional dose of energy is transferred to the primary winding of the transformer from the second capacitor through a closed control key, at the second stage of the period, an additional dose of energy is transferred to the primary winding of the transformer and energy is supplied to the second capacitor from the DC voltage source and the first capacitor through a closed transmitting key, which is in the open state at the first stage of the period, while control switching delays are introduced between the stages of the periods, during which the control signals of the transmitting and control keys correspond to their open state during which they provide a change in the magnitude of the voltages at their power terminals from the corresponding previous stage of the period to the corresponding trace yuschemu step period due to accumulation and respectively connected in parallel recoil energy and transmitting the regulatory keys corresponding capacitors and antiparallel diodes.  2. The method according to claim 1, characterized in that the half-cycle of the oscillation of the circuit of the capacities of the first and second capacitors and the dissipation inductances of the transformers is set to shorter than the duration of the second stage of the period.

Images